Abstract EN:

The goal of this thesis is to understand the role played by a hydrogen layer between a metal (M) and a semiconductor (S) on the formation of the M/S interface. Two synchrotron radiation sources have been used: we performed experiments by high-energy resolution photoemission spectroscopy at LURE and by high spatial resolution spectromicroscopy at ELETTRA. The first chapter of the thesis is dedicated to the motivations that triggered off the measurements on these interfaces and also to a state of the art for the three investigated interfaces (Au/Si(111), Fe/Si(111), Co/Si(111)). The second chapter deals with the description of the experimental techniques used. In this chapter, the complementarity of high spatial resolution and high-energy resolution for photoelectron spectroscopy measurements is pointed out. In the third chapter we explained how to prepare a hydrogenated silicon surface and how to check its spectroscopic signature. The results are presented, analyzed and discussed in the fourth chapter where we show the behavior as a function of the annealing temperature of an interface prepared with 1. 5 ML Au deposited on the hydrogenated silicon surface. In order to separate the different contributions of the high-energy core-level photoemission spectra, as a function of the annealing temperature, we decomposed the spectra in several components associated with elemental Au and Si and components associated with Au-Si reaction. On the same interface after 500ʿC annealing, high spatial resolution core-level spectra revealed tridimensional structures (islands), which have been spectroscopically characterized. We proposed a model for islands formation as a function of the annealing temperature. Some preliminary results on the Fe/Si(111)-H and on the Co/Si(111)-H interfaces with high-energy resolution core-levels spectroscopy are presented.